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Characterization of a high‐resolution 2D transmission ion chamber for independent validation of proton pencil beam scanning of conventional and FLASH dose delivery

Wei Zou, Eric S. Diffenderfer, Kan Ota, P. Boisseau, Michele M. Kim, Yongliang Cai, Stephen Avery, David J. Carlson, R Wiersma, Alexander Lin, Constantinos Koumenis, Keith A. Cengel, James M. Metz, Lei Dong, Boon‐Keng Teo

2021Medical Physics37 citationsDOI

Abstract

INTRODUCTION: Ultra-high dose rate (FLASH) radiotherapy has become a popular research topic with the potential to reduce normal tissue toxicities without losing the benefit of tumor control. The development of FLASH proton pencil beam scanning (PBS) delivery requires accurate dosimetry despite high beam currents with correspondingly high ionization densities in the monitoring chamber. In this study, we characterized a newly designed high-resolution position sensing transmission ionization chamber with a purpose-built multichannel electrometer for both conventional and FLASH dose rate proton radiotherapy. METHODS: The dosimetry and positioning accuracies of the ion chamber were fully characterized with a clinical scanning beam. On the FLASH proton beamline, the cyclotron output current reached up to 350 nA with a maximum energy of 226.2 MeV, with 210 ± 3 nA nozzle pencil beam current. The ion recombination effect was characterized under various bias voltages up to 1000 V and different beam intensities. The charge collected by the transmission ion chamber was compared with the measurements from a Faraday cup. RESULTS: /nC at 100 and 226.2 MeV, respectively. The ion recombination effect increased with larger cyclotron current at lower bias voltage while remaining ≤0.5 ± 0.5% with ≥200 V of bias voltage. Above 200 V, the normalized ion chamber readings demonstrated good linearity with the mass stopping power in air for both clinical and FLASH beam intensities. The spot positioning accuracy was measured to be 0.10 ± 0.08 mm in two orthogonal directions. CONCLUSION: We characterized a transmission ion chamber system under both conventional and FLASH beam current densities and demonstrated its suitability for use as a proton pencil beam dose and spot position delivery monitor under FLASH dose rate conditions.

Topics & Concepts

Faraday cupIonization chamberPencil-beam scanningElectrometerProton therapyDosimetryBeam (structure)Ion beamProtonMaterials scienceOpticsDose profileBeamlineIonAtomic physicsIonizationNuclear physicsNuclear medicinePhysicsMedicineQuantum mechanicsRadiation Therapy and DosimetryAdvanced Radiotherapy TechniquesRadiation Effects in Electronics